JP2021091514A - Paper sheet carrier device - Google Patents

Abstract

To provide a paper sheet carrier device for carrying paper sheets by an air flow generated in a duct, wherein, at the instant when the operation of an air blower for generating an air flow is stopped, the generation of an air flow from the air blower is compulsorily stopped.SOLUTION: A plate (371) rotates with respect to an air blower (330b) between a position of covering a suction port (331) of the air blower (330b) and a position of not covering the suction port (331). When the operation of the air blower (330b) is stopped, the plate (371) shifts to the position of covering the suction port (331), compulsorily stops air suction of the air blower (330b) and thus stops the generation of an air flow from the air blower (330b).SELECTED DRAWING: Figure 10

Description

The present invention relates to a paper leaf transport device for transporting banknotes and other sheet-shaped paper sheets by an air flow generated in a duct.

As an example of such a paper leaf transport device, there is one described in Japanese Patent No. 5926415 (Patent Document 1).
15 to 20 show the paper leaf transport device described in the patent gazette.
This paper leaf transport device includes a carrier 10 that transports the paper leaves by pushing the paper leaves on the front surface thereof, and a duct 11 that has an internal space that is similar to the outer shape of the carrier 10 and allows the carrier 10 to travel. A pair of first blowers 12a and second blowers 12b for bidirectionally traveling the carrier 10 in the duct 11 and stoppers 13a and 13b for stopping the carrier 10 at predetermined positions in the duct 11 are provided.
FIG. 15 is a schematic view showing an environment in which the paper leaf transport device is used.
As shown in FIG. 15, a plurality of pachinko machines 20 and other amusement machines are arranged in a row in the left-right direction of FIG. 15 (in FIG. 15, only one pachinko machine 20 is shown). A bill insertion device 21 for inserting bills is installed next to the table 20.

On the back side of the pachinko machine 20, a duct 11 which is a component of the paper leaf transport device is installed so as to extend parallel to the arrangement direction of the pachinko machine 20.
FIG. 16 is a partial perspective view (including a partially exploded view) of the duct 11.
As shown in FIG. 16, the duct 11 has a hollow structure extending in a straight line, and its vertical cross section has a shape in which a central portion in the vertical direction protrudes inward in a rectangular shape long in the vertical direction. That is, the central portion in the vertical direction constitutes a protruding portion 11a that projects inward of the duct 11 in a rectangular shape.
Further, a slit 11b is formed on the side wall of the duct 11 corresponding to the position of the bill insertion device 21. As will be described later, the banknotes inserted into each banknote insertion device 21 pass through the slit 11b and are sent to the inside of the duct 11.

FIG. 17 is a perspective view of the carrier 10.
The carrier 10 has a central axis 10a extending in the vertical direction, four first wings 10b arranged on one side of the central axis 10a, and four second wings arranged on the other side of the central axis 10a. It consists of 10c.
The first wing 10b is arranged so that the first wing 10b in pairs is V-shaped, starting from the upper end and the lower end of the central axis 10a, respectively. Similarly, the second wing 10c is arranged so that the second wing 10c in pairs is V-shaped, starting from the upper end and the lower end of the central axis 10a, respectively. As will be described later, the banknotes sent to the inside of the duct 11 are conveyed by being pushed by the outer edges of the four first wings 10b.
FIG. 18 is a perspective view showing a state in which the carrier 10 is housed inside the duct 11.
As shown in FIG. 18, the protruding portion 11a of the duct 11 is formed in the space 10d formed between the upper and lower first wings 10b and the space 10d formed between the upper and lower second wings 10c (see FIG. 17). It fits in.
Further, as shown in FIG. 15, at one end (right end in FIG. 15) of the duct 11, a bill storage chamber 14 for storing bills inserted from the bill insertion device 21 and conveyed by the carrier 10 is arranged.

At both ends of the duct 11, a first blower 12a and a second blower 12b that blow air into the duct 11 are arranged.
Only one of the first blower 12a and the second blower 12b operates, or neither of them operates. Both do not work at the same time. When the first blower 12a operates, the second wing 10c of the carrier 10 housed inside the duct 11 receives wind pressure, and the carrier 10 travels in the direction toward the banknote storage chamber 14 (direction X1). On the other hand, when the second blower 12b is activated, the first wing 10b of the carrier 10 housed inside the duct 11 receives the wind pressure, and the carrier 10 travels in the direction away from the banknote storage chamber 14 (direction X2).
Since the bill storage chamber 14 is continuously arranged at one end of the duct 11 (right end in FIG. 15), the second blower 12b is arranged adjacent to the bill storage chamber 14 and provides a bypass passage 12c. It is connected to the duct 11 via.

FIG. 19 is a schematic view showing the internal structure of the bill insertion device 21.
As shown in FIG. 19, the bill insertion device 21 includes a roller unit 21b and a transport path 21c extending in an oblique direction with respect to the duct 11.
The banknotes inserted from the banknote insertion slot 21a of the banknote insertion device 21 are conveyed by the roller unit 21b and are inserted into the duct 11 via the transfer path 21c.
FIG. 20 shows stoppers 13a and 13b for stopping the carrier 10 at predetermined positions (specifically, in the vicinity of both ends of the duct 11) in the duct 11.
The stoppers 13a and 13b are made of hook-shaped members extending inside the duct 11. When the first wing 10b of the carrier 10 is caught by the stopper 13a, the carrier 10 stops in front of the bill storage chamber 14. Further, when the second wing 10c of the carrier 10 is caught by the stopper 13b, the carrier 10 is stopped before the first blower 12a.

The paper leaf transport device having the above structure operates as follows.
When a customer of the pachinko machine 20 inserts a bill into the bill insertion slot 21a of the bill insertion device 21, the bill is conveyed by the roller unit 21b and is inserted into the inside of the duct 11 through the slit 11b of the duct 11 via the transport path 21c. Ru.
The bill insertion device 21 is provided with a bill insertion sensor (not shown), and when a bill is inserted into the duct 11, the bill detection sensor sends a bill insertion signal indicating bill insertion to a central control device (not shown). Send to).
The central control device that receives the bill insertion signal operates the first blower 12a. When the first blower 12a starts operating, an air flow (wind) in the direction (direction X1) toward the bill storage chamber 14 is generated inside the duct 11. The carrier 10 travels in the direction toward the banknote storage chamber 14 (direction X1) when the second wing 10c receives the wind pressure due to this air flow. The carrier 10 captures the banknotes inserted in the duct 11 with the first wing 10b before reaching the banknote storage chamber 14. Since the carrier 10 travels in the direction toward the bill storage chamber 14 (direction X1), the carrier 10 that has captured the bill continues to travel while maintaining the state in which the captured bill is pushed, and then is stopped by the stopper 13a. Be done. When the carrier 10 is stopped, the banknotes are separated from the carrier 10 by the action of inertial force and are stored in the banknote storage chamber 14.

The bills are conveyed by the carrier 10 while maintaining a posture in which the paper surface is parallel to the traveling direction of the carrier 10 (the length direction of the duct 11) and the short side thereof is parallel to the central axis 10a of the carrier 10. Ru.
A sensor (not shown) for detecting the carrier 10 is arranged in the vicinity of the stopper 13a, and when the carrier 10 is stopped by the stopper 13a, the sensor sends a carrier stop signal indicating that the carrier 10 is stopped by the stopper 13a. Send to the central controller.
Upon receiving the carrier stop signal, the central control device stops the operation of the first blower 12a, and a predetermined time (the time required for the bills to be stored in the bill storage chamber 14) after the carrier 10 is stopped by the stopper 13a. ) Has elapsed, the second blower 12b is operated.

When the second blower 12b starts operating, an air flow (wind) in the direction away from the bill storage chamber 14 (direction X2) is generated inside the duct 11. The carrier 10 travels in a direction away from the banknote storage chamber 14 (direction X2) when the first wing 10b receives the wind pressure due to this air flow.
After that, the carrier 10 is caught by the stopper 13b and stops. That is, the carrier 10 returns to the initial position.
The above operation is a one-cycle operation from the insertion of the bill into the bill insertion device 21 to the storage in the bill storage chamber 14.

Japanese Patent No. 5926415 (Japanese Unexamined Patent Publication No. 2016-160038)

Specifically, the first blower 12a and the second blower 12b are composed of a blower. The blower sucks the surrounding air through the suction port by rotating the built-in rotor (fan), and discharges the air (compressed air) from the exhaust port with the pressure of the sucked air increased. ..
As described above, after the carrier 10 has conveyed the banknotes to the banknote storage chamber 14, the second blower 12b is activated to drive the carrier 10 to the initial position (the position at the left end of the duct 11 in FIG. 15). When the carrier 10 returns to its original position, the central controller stops the operation of the second blower 12b.
However, since the second blower 12b is not provided with a brake mechanism for mechanically or electrically stopping the rotor, the rotor can be used even after the central controller has stopped the operation of the second blower 12b. Since the rotation is continued by inertia, the air flow from the second blower 12b is continuously sent in the direction X2 inside the duct 11 until the rotor stops (specifically, 4 to 10 seconds).

While the air flow from the second blower 12b is being sent to the inside of the duct 11, it is inefficient to operate the first blower 12a even if the air flow is small.
Alternatively, the second blower 12b may be provided with a check valve to prevent backflow of air flow, but the check valve remains open while the second blower 12b continues to operate due to inertia. It is in a state. If the first blower 12a is operated with the check valve open, the check valve will not close because the air flow flows into the check valve from the opposite direction. Therefore, the air flow from the first blower 12a flows into the second blower 12b, which may cause a failure of the second blower 12b or a malfunction of the paper leaf transport device.
The present invention has been made in view of the above-mentioned problems in the conventional paper leaf transport device, and even after the second blower 12b has stopped operating, the second blower 12b has been used for a while. It is an object of the present invention to provide a paper leaf transport device capable of preventing the continuous blowing of paper.

In order to achieve the above object, the present invention includes a duct, a carrier running in the duct, a first blower that generates an air flow in one direction in the duct, and the one direction in the duct. A second blower that generates an air flow in the opposite direction is provided, and the carrier is driven in the duct by the air flow generated in the duct by the first blower or the second blower, and the carrier is passed through the carrier. When the operation of the first blower or the second blower is stopped, the first blower or the second blower forcibly generates an air flow after the operation of the first blower or the second blower is stopped. Provided is a paper leaf transport device, which comprises a stopping means for stopping the air.

The stopping means can be configured to stop the generation of air flow by, for example, completely closing the suction port of the first blower or the second blower.
Alternatively, the stopping means includes a plate having a size that totally closes the suction port, and a rotation mechanism that rotates the plate in a plane parallel to a plane defined by the suction port around a point outside the suction port. The rotating mechanism is configured to rotate the plate between a first position that is in contact with the suction port and covers the suction port as a whole and a second position that does not cover the suction port. can do.

Further, the stopping means includes a plate having a size that completely closes the suction port and a moving mechanism that translates the plate in a plane parallel to the surface defined by the suction port. The mechanism can be configured to translate the plate between a first position that is in contact with the suction port and totally covers the suction port and a second position that does not cover the suction port.
Further, the stopping means includes a plate having a size that completely closes the suction port and a moving mechanism that translates the plate in a direction orthogonal to the surface defined by the suction port. Can be configured to translate the plate between a first position that is in contact with the suction port and covers the suction port and a second position that is away from the suction port.

Further, the stopping means includes a plate having a size that totally closes the suction port, and a rotation mechanism that rotates the plate in a plane orthogonal to a plane defined by the suction port around a point outside the suction port. The rotating mechanism is configured to rotate the plate between a first position that is in contact with the suction port and covers the suction port as a whole and a second position that does not cover the suction port. can do.

Further, the stopping means is a plurality of plates having a size of partially closing the suction port, and all the plates can cooperate with each other to completely close the suction port. The rotation mechanism includes the same number of rotation mechanisms as the number of plates, which rotate each of the plurality of plates in a plane orthogonal to the plane defined by the suction port around a point outside the suction port. Each is configured to rotate each of the plurality of plates between a first position that is in contact with the suction port and partially covers the suction port and a second position that does not cover the suction port. Can be done.

According to the paper leaf transport device according to the present invention, after the operation of the second blower 12b is stopped, the generation of the air flow from the second blower 12b is forcibly stopped by the stopping means. Specifically, the stop means completely blocks the suction port of the second blower 12b, so that the generation of the air flow is stopped.
Therefore, after the operation of the second blower 12b is stopped, the air blown from the second blower 12b is surely stopped, so that the first blower 12a is operated from the stage immediately after the second blower 12b is stopped. This makes it possible to avoid a failure of the second blower 12b or a malfunction of the paper leaf transport device, and by extension, the efficiency of banknote transport by the paper leaf transport device can be improved.

It is the schematic which shows the environment in which the paper leaf transport apparatus which concerns on 1st Embodiment of this invention is used. It is a perspective view of the carrier which forms one component of the paper leaf transfer apparatus shown in FIG. 3 (A) is a front view of the carrier shown in FIG. 2, FIG. 3 (B) is a plan view of the carrier when viewed from above, FIG. 3 (C) is a bottom view of the carrier, and FIG. 3 (D) is a bottom view of the carrier. It is a side view of a carrier. It is a perspective view of the first carrier member which is a component component of the carrier shown in FIG. It is a perspective view of the 2nd carrier member which is a component component of the carrier shown in FIG. It is a perspective view of the duct which forms one component of the paper leaf transport device shown in FIG. It is a partial vertical sectional view of the paper leaf transport device which concerns on 1st Embodiment of this invention.

It is a partial vertical sectional view of the paper leaf transport device which concerns on 1st Embodiment of this invention. It is an enlarged perspective view of the 2nd blower in the paper leaf transfer apparatus which concerns on 1st Embodiment of this invention. It is the schematic of the stopping means in 1st Embodiment of this invention. 11 (A) and 11 (B) are schematic views of the stopping means in the second embodiment of the present invention. 12 (A) and 12 (B) are schematic views of the stopping means in the third embodiment of the present invention. 13 (A) and 13 (B) are schematic views of the stopping means according to the fourth embodiment of the present invention.

14 (A), 14 (B) and 14 (C) are schematic views of the stopping means according to the fifth embodiment of the present invention. It is the schematic which shows the environment in which the conventional paper leaf transport device is used. FIG. 15 is a partial perspective view (including a partially exploded view) of a duct which is a component of the conventional paper leaf transport device shown in FIG. It is a perspective view of the carrier which is one component of the conventional paper leaf transport apparatus shown in FIG. It is a perspective view which shows the state which the carrier shown in FIG. 17 is housed in the duct shown in FIG. It is the schematic which shows the internal structure of the banknote insertion apparatus which is one component of the conventional paper leaf transport apparatus shown in FIG. It is sectional drawing which shows the stopper which is one component of the conventional paper leaf transport apparatus shown in FIG.

(First Embodiment)
FIG. 1 is a schematic view showing an environment in which the paper leaf transport device 300 according to the first embodiment of the present invention is used.
The paper leaf transport device 300 has a carrier 310 that transports banknotes by pushing the banknotes on the front surface thereof, a duct 320 that has an internal space that is similar to the outer shape of the carrier 310 and has an internal space in which the carrier 310 can travel, and the inside of the duct 320. A pair of first blower 330a and a second blower 330b for bidirectionally traveling the carrier 310, and a pair of stoppers (not shown) for stopping the carrier 310 at a predetermined position in the duct 320. There is.
As shown in FIG. 1, a plurality of pachinko machines and other amusement machines 400 are arranged in a row in the left-right direction of FIG. 1 (however, in FIG. 1, only one pachinko machine 400 is shown). , A game medium rental machine 401 is installed next to each pachinko machine 400. When a bill is inserted, the game medium lending machine 401 pays out a number of game media according to the amount of the bill.

On the back surface side of the pachinko machine 400, a duct 320, which is a component of the paper leaf transport device 300, is installed so as to extend parallel to the arrangement direction of the pachinko machine 400 (left-right direction in FIG. 1).
2A and 2B are perspective views of the carrier 310, FIG. 3A is a front view of the carrier 310, FIG. 3B is a plan view of the carrier 310 when viewed from above, and FIG. 3C is a view of the carrier 310. The bottom view and FIG. 3D are side views of the carrier 310.
The carrier 310 is composed of a first carrier member 311 and a second carrier member 312.
FIG. 4 is a perspective view of the first carrier member 311 and FIG. 5 is a perspective view of the second carrier member 312.
Hereinafter, as shown in FIG. 2, the direction in which the short side of the first carrier member 311 extends (the left-right direction in FIG. 2) is the direction orthogonal to the first direction D1 and the first direction D1, and the first carrier member 311. The direction in which the long side extends (the vertical direction in FIG. 2) is defined as the second direction D2, and the direction orthogonal to both the first direction D1 and the second direction D2 is defined as the third direction D3.

As shown in FIG. 4, the first carrier member 311 is made of a frame-shaped plate material, and has a substantially rectangular cross section when viewed from a direction orthogonal to the thickness direction of the plate material. The width of the plate material constituting the first carrier member 311 is constant.
As shown in FIG. 3D, arc-shaped reinforcing members 313 are provided at the four corners of the inner wall of the first carrier member 311 over two sides adjacent to each other.
As shown in FIG. 5, the second carrier member 312 is made of a frame-shaped plate material, and the cross section when viewed from a direction orthogonal to the thickness direction of the plate material has a shape substantially close to a rectangle. The width of the plate material constituting the second carrier member 312 is constant.
The second carrier member 312 is formed with recesses 314 from the outside to the inside of the second carrier member 312 on a pair of opposite sides (sides corresponding to the short sides of the rectangle).

Each of the recesses 314 is a pair of first members 314A extending parallel to each other from the outside to the inside of the second carrier member 312, and one end of each of the pair of first members 314A (second carrier member 312). It is composed of a second member 314B connecting (ends located inside the) and a pair of third members 314C extending so as to be close to each other from the other end of each of the pair of first members 314A. There is.
As shown in FIG. 2, the second carrier member 312 is fitted into the first carrier member 311 from the inside of the first carrier member 311 via the recess 314. At this time, the first carrier member 311 is in a state of being fitted between the second member 314B of the recess 314 and the pair of third members 314C. That is, since the first carrier member 311 is sandwiched between the second member 314B of the recess 314 and the pair of third members 314C on the front surface side and the back surface side, respectively, the first carrier member 311 and the second carrier member It is strongly connected to and from the 312, and the first carrier member 311 does not easily come off from the second carrier member 312.

All or some of the corners of the first carrier member 311 and the second carrier member 312 are chamfered or formed in a curved shape.
Further, as shown in FIG. 3D, of the portions constituting the second carrier member 312, both side edges (side edges above and below FIG. 3D) of the portion 312A extending in the first direction D1 are curved. The shape of the taper 312B is formed. The taper 312B is formed over a certain length from both ends of the portion 312A (both ends in the left-right direction of FIG. 3D), and the width of the portion 312A (the length in the second direction D2) is formed at both ends of the portion 312A. The closer it is, the smaller it is set.
By forming the taper 312B in the portion 312A of the second carrier member 312, the resistance of the carrier 310 to the upper and lower inner walls of the second space 322 (see FIG. 6) of the duct 320 when traveling in the duct 320 is reduced. Therefore, the traveling of the carrier 310 can be stabilized.

FIG. 6 is a perspective view of the duct 320.
As shown in FIG. 6, the duct 320 is similar to the outer shape of the carrier 310 and has an internal space having a minimum cross-sectional area within a range in which the carrier 310 can travel.
Specifically, the internal space of the duct 320 has a first space 321 having a rectangular cross section having a long side extending in the second direction D2 and a third direction from the center to the outside in the second direction D2 of the first space 321. It consists of a pair of second spaces 322 extending to D3. Each of the second space 322 has a rectangular cross section, and the lengths of the second space 322 in the third direction D3 are equal to each other.
The first carrier member 311 of the carrier 310 runs inside the first space 321 and the portion of the second carrier member 312 of the carrier 310 protruding outward from the first carrier member 311 passes through the inside of each second space 322. Run. The banknotes inserted into the duct 320 are pushed by the first carrier member 311 of the carrier 310 and travel inside the first space 321.
The duct 320 is made of, for example, transparent plastic.

As shown in FIG. 1, at one end (the right end of FIG. 1) of the duct 320, a bill taking device (not shown, a device corresponding to the bill insertion device 21 shown in FIG. 19) is installed from the game medium lending machine 401. A banknote storage chamber 340 that is inserted into the duct 320 via the duct 320 and stores the banknotes conveyed by the carrier 310 is arranged.
The first blower 330a and the second blower 330b that send the air flow into the duct 320 are arranged at both ends of the duct 320.
Only one of the first blower 330a and the second blower 330b operates, or neither of them operates. Both do not work at the same time. When the first blower 330a is activated, the carrier 310 housed inside the duct 320 receives the wind pressure and travels in the direction toward the banknote storage chamber 340 (direction X1). On the other hand, when the second blower 330b is activated, the carrier 310 housed inside the duct 320 receives the wind pressure and travels in the direction away from the banknote storage chamber 340 (direction X2).

The first blower 330a is connected to one end of the duct 320 (the left end in FIG. 1), but the other end of the duct 320 (the right end in FIG. 1) is continuously connected to the end of the banknote storage chamber 340. Is arranged, the second blower 330b is arranged adjacent to the bill storage chamber 340 and is connected to the duct 320 via the bypass passage 330c.
Further, the paper leaf transport device 300 according to the present embodiment is additionally provided with a check valve 360 including a partition wall 350 and a spring member 351.
7 and 8 are partial vertical sectional views of the paper leaf transport device 300 according to the present embodiment. 7 and 8 both show a part including the end of the duct 320 (the left end of the duct 320 in FIGS. 7 and 8), a bill storage chamber 340, and a bill transport path 321 extending from the end of the duct 320 to the bill storage chamber 340. It is a cross-sectional view of the region including the second blower 330b and the bypass passage 330c (note that the left and right directions are reversed in FIG. 1, FIG. 7 and FIG. 8), and FIG. 7 shows the partition wall 350 closed. State, FIG. 8 shows a state in which the partition wall 350 is open.

The partition wall 350 is installed inside the banknote transport path 321 along the inner wall of the banknote transport path 321. Of both ends of the banknote transport path 321 in the length direction, the end closer to the bill storage chamber 340 is used. It is rotatably configured with respect to the bypass passage 330c as the center. That is, the partition wall 350 rotates between a state of being closed with respect to the bypass passage 330c (state of FIG. 7) and a state of being open with respect to the bypass passage 330c (state of FIG. 8).
The size of the partition wall 350 is such that when the partition wall 350 is closed with respect to the bypass passage 330c (state in FIG. 7), the bypass passage 330c can be completely closed and the partition is formed. When the wall 350 is opened with respect to the bypass passage 330c (state of FIG. 8), the size of the other end of the partition wall 350 is in contact with the upper surface of the bill transport path 321. That is, the partition wall 350 is the bill transport path 321. It is a size that can block the whole.

The spring member 351 is a tension spring, one end of which is fixed to the inner surface of the bypass passage 330c, and the other end of which is fixed to the back surface of the partition wall 350 (the surface on the side leading to the bypass passage 330c). Therefore, the spring member 351 urges the partition wall 350 in the direction in which the partition wall 350 closes the bypass passage 330c, and as shown in FIG. 7, when the banknotes have not been conveyed, the partition wall 350 bypasses. The state of blocking the passage 330c is maintained.
As will be described later, when the second blower 330b is activated, the partition wall 350 rotates and opens with respect to the bypass passage 330c because the wind force generated by the air flow from the second blower 330b exceeds the tensile force of the spring member 351. It shifts to the state (the state shown in FIG. 8).

The paper leaf transport device 300 having the above structure operates as follows.
When a customer of the pachinko machine 400 inserts banknotes into the game medium lending machine 401, a number of game media corresponding to the amount of the banknotes are paid out from the game medium lending machine 401. The bills inserted into the game medium lending machine 401 are discharged from the back surface of the game medium lending machine 401, taken into the bill taking-in device, and then put into the inside of the duct 320 from the bill taking-in device.
The game medium lending machine 401 is provided with a bill detection sensor (not shown), and when a bill is inserted into the duct 320, the bill detection sensor sends a bill insertion signal indicating the bill insertion to the central control device (FIG. (Not shown) to send.
The central control device that receives the bill insertion signal operates the first blower 330a. When the first blower 330a starts operating, an air flow in the direction (direction X1) toward the bill storage chamber 340 is sent to the inside of the duct 320. The carrier 310 receives the wind pressure from this air flow and starts traveling in the direction toward the banknote storage chamber 340 (direction X1).

The carrier 310 catches the banknotes inserted into the duct 320 via the banknote taking-in device on the front surface of the first carrier member 311 before reaching the banknote storage chamber 340. The carrier 310 that has captured the banknotes continues to travel in the direction (direction X1) toward the banknote storage chamber 340 while maintaining the state in which the captured banknotes are pushed, and is then stopped by a stopper (not shown). When the carrier 310 is stopped, the banknotes are separated from the carrier 310 by the action of inertial force and are stored in the banknote storage chamber 340.
The partition wall 350 is closed by the action of the spring member 351 until the banknotes are separated from the carrier 310 and stored in the banknote storage chamber 340. Therefore, the banknotes can be stored in the banknote storage chamber 340 without being caught on the peripheral edge of the bypass passage 330c.

A sensor (not shown) for detecting the carrier 310 is arranged in the vicinity of the stopper, and when the carrier 310 is stopped by the stopper, the sensor transmits a carrier stop signal indicating the stop of the carrier 310 to the central control device.
Upon receiving the carrier stop signal, the central control device stops the operation of the first blower 330a and a predetermined time after the carrier 310 is stopped by the stopper (the time required for the bills to be stored in the bill storage chamber 340). When the time has passed, the second blower 330b is operated.
When the second blower 330b starts operating, an air flow is sent to the bypass passage 330c. The partition wall 350 closes the bypass passage 330c by the urging force of the spring member 351. However, as shown in FIG. 8, the partition wall 350 has the urging force of the spring member 351 due to the wind pressure of the air flow generated by the second blower 330b. It rotates until the other end touches the upper surface of the bill transport path 321 against the above.

As a result, the banknote transport path 321 leading to the banknote storage chamber 340 is blocked by the partition wall 350, and the bypass passage 330c and the duct 130 communicate with each other. As a result, the air flow from the second blower 330b is sent to the duct 130, and the carrier 310 inside the duct 130 receives the wind pressure from this air flow and moves away from the bill storage chamber 340 (direction X2 in FIG. 1). Start running.
When the carrier 310 collides with a stopper (not shown) in front of the start end (left end in FIG. 1) of the duct 320 and stops, the sensor (not shown) detects the carrier 310 and transmits a detection signal to the central control device. To do. The central control device that receives the detection signal from the sensor stops the operation of the second blower 330b.

When the second blower 330b stops operating, the partition wall 350 returns to the position where the bypass passage 330c is closed again by the urging force of the spring member 351 (state of FIG. 7).
The above is one cycle of the operation of the paper leaf transport device 300 according to the present embodiment. After that, this cycle is repeated.
As described above, since the conventional second blower 12b is not provided with a brake mechanism for mechanically or electrically stopping the rotor, it is after the central controller stops the operation of the second blower 12b. However, the rotor continues to rotate due to inertia. Therefore, the air flow from the second blower 12b continues to be sent in the direction X2 inside the duct 11 until the rotor stops (specifically, 4 to 10 seconds). Therefore, the check valve 360 remains open while the second blower 12b continues to operate due to inertia. If the first blower 12a is operated with the check valve 360 open, the air flow from the first blower 12a passes through the check valve 360 and flows into the bypass passage 12c, so that the check valve 360 cannot be closed. , It becomes impossible to maintain the normal operation of the paper leaf transport device 300.

Therefore, the paper leaf transport device 300 according to the present embodiment is provided with a stop means 370 for forcibly stopping the generation of air flow by the second blower 330b after the operation of the second blower 330b is stopped. ing. As illustrated below, the stopping means 370 forcibly stops the generation of the air flow from the second blower 330b by closing the entire suction port of the second blower 330b.
FIG. 9 is an enlarged perspective view of the second blower 330b.
As shown in FIG. 9, the second blower 330b includes a circular suction port 331. The second blower 330b sucks the surrounding air through the suction port 331 by rotating the built-in rotor (not shown), and the duct 320 sucks the compressed air through the bypass passage 330c. Send out to the inside of.

FIG. 10 is a schematic view of the stopping means 370 according to the present embodiment.
The stopping means 370 is a circular plate 371 having a size that totally closes the suction port 331, and a surface defined by the suction port 331 centered on a point outside the suction port 331 (in FIG. 10, the paper surface of FIG. 10). It is provided with a rotation mechanism 372 that rotates the plate 371 in a plane parallel to the plate 371.
The rotation mechanism 372 is composed of, for example, a step motor, or a combination of a solenoid and a changing mechanism that converts the linear motion of the iron core by the solenoid into rotary motion.
In the rotation mechanism 372, the plate 371 is in contact with the suction port 331 and the first position (the position shown by the broken line in FIG. 10) that covers the suction port 331 as a whole, and the plate 371 is separated from the suction port 331 to separate the suction port 331. Rotate the plate 371 to and from the uncovered second position (the solid line position in FIG. 10).

The stopping means 370 operates as follows.
The plate 371 is located at the second position (the position of the solid line in FIG. 10) while the first blower 330a and the second blower 330b are operating.
When the central control device stops the operation of the second blower 330b, the central control device stops the second blower 330b and at the same time activates the rotation mechanism 372 to move the plate 371 from the second position to the first position (FIG. 10). Move to the position of the broken line).
As the plate 371 shifts to the first position, the suction port 331 of the second blower 330b is completely blocked by the plate 371, so that the second blower 330b cannot take in air, and by extension, bypasses. It is also impossible to send air into the duct 320 through the passage 330c.

As described above, by providing the stopping means 370, the generation of the air flow from the second blower 330b is forcibly stopped from the stage immediately after the operation of the second blower 330b is stopped. Therefore, after the operation of the second blower 330b is stopped, the air blown from the second blower 330b is surely stopped, so that the first blower 330a can be operated from the stage immediately after the second blower 330b has stopped operating. It will be possible.
The plate 371, for example, shifts from the first position to the second position at the same time when the first blower 330a starts operating.

(Second embodiment)
The paper leaf transport device according to the second embodiment of the present invention includes a stopping means 370A instead of the stopping means 370 in the first embodiment. Except for this point, the paper leaf transport device according to the present embodiment has the same structure as the paper leaf transport device 300 according to the first embodiment.
11A and 11B are schematic views of the stopping means 370A, FIG. 11A shows a case where the stopping means 370A is in a second position where the suction port 331 of the second blower 330b is not blocked, and FIG. 11B shows a stop. The case where the means 370A is in the first position which closes the suction port 331 of the second blower 330b is shown.
The stopping means 370A has a circular plate 371 having a size that completely closes the suction port 331, and the plate 371 in a plane parallel to the surface defined by the suction port 331 (paper surface in FIG. 11 in FIG. 11). It is provided with a moving mechanism 373 that moves in parallel.
The moving mechanism 373 is in contact with the suction port 331 and has a first position (position shown in FIG. 11B) that covers the suction port 331 as a whole and a second position that does not cover the suction port 331 (FIG. 11 (A)). The plate 371 is translated with respect to the position shown in (1).

The stopping means 370A operates as follows.
The plate 371 is located at the second position (the position shown in FIG. 11A) while the first blower 330a and the second blower 330b are operating.
When the central controller stops the operation of the second blower 330b, the central controller stops the second blower 330b and at the same time activates the moving mechanism 373 to move the plate 371 from the second position to the first position (FIG. 11 (FIG. 11). Move to the position shown in B)).
As the plate 371 shifts to the first position, the suction port 331 of the second blower 330b is completely blocked by the plate 371, so that the second blower 330b cannot take in air, and by extension, bypasses. It is also impossible to send air into the duct 320 through the passage 330c.
As described above, by providing the stopping means 370A, the generation of the air flow from the second blower 330b is forcibly stopped from the stage immediately after the operation of the second blower 330b is stopped. Therefore, after the operation of the second blower 330b is stopped, the air blown from the second blower 330b is surely stopped, so that the first blower 330a can be operated from the stage immediately after the second blower 330b has stopped operating. It will be possible.
The plate 371, for example, shifts from the first position to the second position at the same time when the first blower 330a starts operating.

(Third embodiment)
The paper leaf transport device according to the third embodiment of the present invention includes the stopping means 370B instead of the stopping means 370 in the first embodiment. Except for this point, the paper leaf transport device according to the present embodiment has the same structure as the paper leaf transport device 300 according to the first embodiment.
FIG. 12 is a schematic view of the stop means 370B, FIG. 12 (A) shows a case where the stop means 370B is in the second position where the suction port 331 of the second blower 330b is not blocked, and FIG. 12 (B) shows the case where the stop means 370B is stopped. The case where the means 370B is in the first position to close the suction port 331 of the second blower 330b is shown.
The stopping means 370B is a moving mechanism that translates the circular plate 371 having a size that completely closes the suction port 331 and the plate 371 in the direction orthogonal to the plane defined by the suction port 331 (vertical direction in FIG. 12). 374 and.

The moving mechanism 374 is in contact with the suction port 331, and is separated from the first position (position shown in FIG. 12B) that totally covers the suction port 331 and the suction port 331, and is in contact with the suction port 331. The plate 371 is translated with and from the second position (the position shown in FIG. 12 (A)).
The stopping means 370B operates as follows.
The plate 371 is located at the second position (the position shown in FIG. 12A) while the first blower 330a and the second blower 330b are operating.
When the central control device stops the operation of the second blower 330b, the central control device stops the second blower 330b and at the same time activates the moving mechanism 374 to move the plate 371 from the second position to the first position (FIG. 12 (FIG. 12). Move to the position shown in B)).
As the plate 371 shifts to the first position, the suction port 331 of the second blower 330b is completely blocked by the plate 371, so that the second blower 330b cannot take in air, and by extension, bypasses. It is also impossible to send air into the duct 320 through the passage 330c.

As described above, by providing the stopping means 370B, the generation of the air flow from the second blower 330b is forcibly stopped from the stage immediately after the operation of the second blower 330b is stopped. Therefore, after the operation of the second blower 330b is stopped, the air blown from the second blower 330b is surely stopped, so that the first blower 330a can be operated from the stage immediately after the second blower 330b has stopped operating. It will be possible.
The plate 371, for example, shifts from the first position to the second position at the same time when the first blower 330a starts operating.

(Fourth Embodiment)
The paper leaf transport device according to the fourth embodiment of the present invention includes a stopping means 370C instead of the stopping means 370 in the first embodiment. Except for this point, the paper leaf transport device according to the present embodiment has the same structure as the paper leaf transport device 300 according to the first embodiment.
FIG. 13 is a schematic view of the stop means 370C, FIG. 13 (A) shows the case where the stop means 370C is in the second position where the suction port 331 of the second blower 330b is not blocked, and FIG. 13 (B) shows the case where the stop means 370C is stopped. The case where the means 370C is in the first position which closes the suction port 331 of the second blower 330b is shown.
The stopping means 370C rotates the plate 371 in a plane orthogonal to the plane defined by the suction port 331 about a circular plate 371 having a size that completely closes the suction port 331 and a point outside the suction port 331. It is equipped with a rotation mechanism 375. While the plate 371 is rotating, the surface of the plate 371 is in a state orthogonal to the rotation direction of the plate 371.

The plate 371 is connected to the rotation mechanism 375 at a point on its circumference, and the rotation mechanism 375 is in the first position (at the first position (FIG. 13B), which is in contact with the suction port 331 and totally covers the suction port 331. The plate 371 is rotated between the position shown) and the second position (position shown in FIG. 13A) that does not cover the suction port 331.
The stopping means 370C operates as follows.
The plate 371 is located at the second position (the position shown in FIG. 13A) while the first blower 330a and the second blower 330b are operating.
When the central control device stops the operation of the second blower 330b, the central control device stops the second blower 330b and at the same time activates the rotation mechanism 375 to move the plate 371 from the second position to the first position (FIG. 13 (FIG. 13). Move to the position shown in B)).

As the plate 371 shifts to the first position, the suction port 331 of the second blower 330b is completely blocked by the plate 371, so that the second blower 330b cannot take in air, and by extension, bypasses. It is also impossible to send air into the duct 320 through the passage 330c.
As described above, by providing the stopping means 370C, the generation of the air flow from the second blower 330b is forcibly stopped from the stage immediately after the operation of the second blower 330b is stopped. Therefore, after the operation of the second blower 330b is stopped, the air blown from the second blower 330b is surely stopped, so that the first blower 330a can be operated from the stage immediately after the second blower 330b has stopped operating. It will be possible.
The plate 371, for example, shifts from the first position to the second position at the same time when the first blower 330a starts operating.

(Fifth Embodiment)
The paper leaf transport device according to the fifth embodiment of the present invention includes the stopping means 370D instead of the stopping means 370 in the first embodiment. Except for this point, the paper leaf transport device according to the present embodiment has the same structure as the paper leaf transport device 300 according to the first embodiment.
FIG. 14 is a schematic view of the stopping means 370D, FIG. 14A shows a case where the stopping means 370D is in a second position where the suction port 331 of the second blower 330b is not blocked, and FIG. 14B shows a stop. A case where the means 370D is in the first position to block the suction port 331 of the second blower 330b is shown, and FIG. 14C is a plan view of the stopping means 370D in the first position when viewed from above the second blower 330b. Is.

The stopping means 370D is a rotating mechanism that rotates each of the two semicircular plates 376a and 376b and the plates 376a and 376b in a plane orthogonal to the plane defined by the suction port 331 about a point outside the suction port 331. It includes 377a and 377b. While the plates 376a and 376b are rotating, the surfaces of the plates 376a and 376b are in a state orthogonal to the rotation direction of the plates 376a and 376b.
Each plate 376a and 376b is connected to a rotation mechanism 377a and 377b at a semicircular apex, and the rotation mechanism 377a and 377b are in contact with the suction port 331 and partially cover the suction port 331 in the first position (FIG. Each of the plates 376a and 376b is rotated between the position shown in 14 (B) and the second position (position shown in FIG. 14A) that is separated from the suction port 331 and does not cover the suction port 331.

The stopping means 370D operates as follows.
The plates 376a and 376b are located at the second position (the position shown in FIG. 14A) while the first blower 330a and the second blower 330b are operating.
When the central controller stops the operation of the second blower 330b, the central controller stops the second blower 330b and at the same time activates the rotation mechanisms 377a and 377b to position the plates 376a and 376b from the second position to the first position. (Position shown in FIG. 14B) is shifted.
Since each plate 376a and 376b has a semicircular shape, when each plate 376a and 376b shifts to the first position, the plates 376a and 376b cooperate to form a circular plate. As a result, as shown in FIG. 14C, the suction port 331 is totally closed by the two plates 376a and 376b.

When the plates 376a and 376b are moved to the first position and the suction port 331 of the second blower 330b is blocked by the plates 376a and 376b, the second blower 330b cannot take in air, and thus the bypass passage. It is also impossible to send air into the duct 320 via the 330c.
As described above, by providing the stopping means 370D, the generation of the air flow from the second blower 330b is forcibly stopped from the stage immediately after the operation of the second blower 330b is stopped. Therefore, after the operation of the second blower 330b is stopped, the air blown from the second blower 330b is surely stopped, so that the first blower 330a can be operated from the stage immediately after the second blower 330b has stopped operating. It will be possible.
The plates 376a and 376b, for example, shift from the first position to the second position at the same time when the first blower 330a starts operating.

In this embodiment, two semicircular plates 376a and 376b are used, but the number and shape of the plates are not limited thereto. A plurality of plates having a size that partially closes the suction port 331, and when all the plates move to the first position, all the plates cooperate to completely close the suction port 331. Any number and shape of plates can be used as long as the plates can be used.
In the first to fifth embodiments described above, an example is shown in which the output of the second blower 330b is forcibly stopped via the stopping means 370, 370A-370D, but the stopping means 370, 370A-370D is used. It is also possible to forcibly stop the output of the first blower 330a.

300 Paper leaf transport device according to the first embodiment of the present invention 310 Carrier 320 Duct 330a First blower 330b Second blower 340 Banknote storage room 370, 370A-370D Stop means 371 Plate 372 Rotation mechanism 400 Amusement machine 401 Game medium Rental machine

Claims (7)

With the duct
A carrier running in the duct and
The first blower that generates an air flow in one direction in the duct,
A second blower that generates an air flow in the duct in the direction opposite to the one direction,
In a paper leaf transport device, the carrier is driven in the duct by the air flow generated in the duct by the first blower or the second blower, and the paper leaves are conveyed through the carrier. ,
A paper sheet provided with a stopping means for forcibly stopping the generation of air flow by the first blower or the second blower after the operation of the first blower or the second blower is stopped. Class transfer device. The paper leaf transport according to claim 1, wherein the stopping means stops the generation of an air flow by totally closing the suction port of the first blower or the second blower. apparatus. The stopping means is
A plate having a size that completely closes the suction port and
A rotating mechanism that rotates the plate in a plane parallel to the plane defined by the suction port around a point outside the suction port.
With
The rotation mechanism is characterized in that the plate is rotated between a first position that is in contact with the suction port and covers the suction port as a whole and a second position that does not cover the suction port. The paper leaf transport device according to claim 2. The stopping means is
A plate having a size that completely closes the suction port and
A moving mechanism that translates the plate in a plane parallel to the plane defined by the suction port.
With
The moving mechanism is characterized in that the plate is translated between a first position that is in contact with the suction port and covers the suction port as a whole and a second position that does not cover the suction port. The paper leaf transport device according to claim 2. The stopping means is
A plate having a size that completely closes the suction port and
A moving mechanism that translates the plate in a direction orthogonal to the plane defined by the suction port.
With
The moving mechanism is characterized in that the plate is translated between a first position which is in contact with the suction port and covers the suction port and a second position which is away from the suction port. The paper leaf transport device according to 2. The stopping means is
A plate having a size that completely closes the suction port and
A rotation mechanism that rotates the plate in a plane orthogonal to the plane defined by the suction port around a point outside the suction port.
With
The rotation mechanism is characterized in that the plate is rotated between a first position that is in contact with the suction port and covers the suction port as a whole and a second position that does not cover the suction port. The paper leaf transport device according to claim 2. The stopping means is
A plurality of plates having a size of partially closing the suction port, and a plate in which all the plates can cooperate to completely close the suction port.
A rotation mechanism as many as the number of the plates, which rotates each of the plurality of plates in a plane orthogonal to the plane defined by the suction port around a point outside the suction port.
With
Each of the rotation mechanisms rotates each of the plurality of plates between a first position that is in contact with the suction port and partially covers the suction port and a second position that does not cover the suction port. The paper leaf transport device according to claim 2, wherein the paper leaf transport device is characterized by the above.

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